1. Leo Lam © 2010-2011 Signals and Systems EE235 Lecture 20

2. Leo Lam © 2010-2011 Today’s menu Exponential response of LTI system

3. Leo Lam © 2010-2011 3 What is y(t) if ? Given a specific s, H(s) is a constant S Output is just a constant times the input

4. Exponential response of LTI system Leo Lam © 2010-2011 4 LTI Varying s, then H(s) is a function of s H(s) becomes a Transfer Function of the input If s is “frequency”… Working toward the frequency domain

5. Eigenfunctions Leo Lam © 2010-2011 5 Definition: An eigenfunction of a system S is any non-zero x(t) such that Where is called an eigenvalue. Example: What is the y(t) for x(t)=e at for e at is an eigenfunction; a is the eigenvalue S{x(t)}

6. Eigenfunctions Leo Lam © 2010-2011 6 Definition: An eigenfunction of a system S is any non-zero x(t) such that Where is called an eigenvalue. Example: What is the y(t) for x(t)=e at for e at is an eigenfunction; 0 is the eigenvalue S{x(t)}

7. Eigenfunctions Leo Lam © 2010-2011 7 Definition: An eigenfunction of a system S is any non-zero x(t) such that Where is called an eigenvalue. Example: What is the y(t) for x(t)=u(t) u(t) is not an eigenfunction for S

8. Recall Linear Algebra Leo Lam © 2010-2011 8 Given nxn matrix A, vector x, scalar x is an eigenvector of A, corresponding to eigenvalue if Ax=x Physically: Scale, but no direction change Up to n eigenvalue-eigenvector pairs (x i, i )

9. Exponential response of LTI system Leo Lam © 2010-2011 9 Complex exponentials are eigenfunctions of LTI systems For any fixed s (complex valued), the output is just a constant H(s), times the input Preview: if we know H(s) and input is e st, no convolution needed! S

10. LTI system transfer function Leo Lam © 2010-2011 10 LTI e st H(s)e st s is complex H(s): two-sided Laplace Transform of h(t)

11. LTI system transfer function Leo Lam © 2010-2011 11 Let s=j  LTI systems preserve frequency Complex exponential output has same frequency as the complex exponential input LTI e st H(s)e st LTI

12. LTI system transfer function Leo Lam © 2010-2011 12 Example: For real systems (h(t) is real): where and LTI systems preserve frequency LTI

13. Importance of exponentials Leo Lam © 2010-2011 13 Makes life easier Convolving with e st is the same as multiplication Because e st are eigenfunctions of LTI systems cos(t) and sin(t) are real Linked to e st

14. Quick note Leo Lam © 2010-2011 14 LTI e st H(s)e st LTI e st u(t) H(s)e st u(t)

15. Which systems are not LTI? Leo Lam © 2010-2011 15 NOT LTI

16. Leo Lam © 2010-2011 Summary Eigenfunctions/values of LTI System